JP5071595B2 - Printing apparatus and printing method - Google Patents

Description

  The present invention relates to printing technology using dark and light inks, and more specifically, a printing apparatus that prints a multi-tone image by controlling the distribution of each dot of two or more kinds of light and dark inks based on a tone signal representing an image. The present invention relates to a cartridge used therefor, an image recording method, and a computer program product for realizing the method.

  2. Description of the Related Art In recent years, color printers that eject several colors of ink from a head have become widespread as computer output devices, and are widely used for printing images processed by a computer or the like in multiple colors and multiple gradations. When printing a multicolor image with three colors of cyan, magenta, and yellow (CMY), the size of the dots formed on the paper by the ink ejected at a time is constant and printed. The gradation of the image is expressed by the dot density (recording density per unit area). The density of dots that can be formed per predetermined length has been increasing year by year, but in the case of a printer, it remains at about 300 to 720 dpi, and there is still a large gap with the expressive power of silver halide photography. The resolution in a silver circle film is said to be several thousand dpi.

  In a printer that expresses an image by whether or not there is a dot (also referred to as dot on / off), dots are formed sparsely in a region where the image density is low, that is, a region where the printed dot density is low. As it happens, the dots are visible. Therefore, for the purpose of further improving the printing quality, printing apparatuses and printing methods using dark and light inks have been proposed. This is intended to realize printing with excellent gradation expression by preparing inks with high density and low density for the same color and controlling the ejection of both inks. For example, the following patent document includes a head that forms two types of light and dark dots for the same color, and the number of light and dark dots formed in a predetermined dot matrix and the overlap thereof according to the density information of the input image. A recording method and apparatus for recording a multi-tone image by controlling it are disclosed.

JP 61-108254 A

  However, in conventional printing apparatuses using light and dark inks, there is no particular consideration on how high-density inks and low-density inks correspond to the tone signals of the original image. In this case, the tone signals of the image are simply assigned in order from the ink having the lowest density (for example, JP-A-2-215541, FIG. 9).

  One object of the present invention is to appropriately correspond high-density ink and low-level ink to the tone signal of the original image in a printing apparatus capable of ejecting two or more types of light and shade for the same color, The object is to improve the quality of recorded images. In particular, one of the objects is to improve the expression of the low density area in the original image or the expression in the area transitioning from the low density area to the high density area. Another object of the present invention is to propose a cartridge suitable for such a printing apparatus.

In order to achieve at least one of these objects, the first printing apparatus of the present invention provides:
A printing apparatus that prints an image with multiple colors of ink, a nozzle for ejecting magenta ink, a nozzle for ejecting light magenta ink, a nozzle for ejecting cyan ink, and ejecting yellow ink With a nozzle to do
The light magenta ink and the magenta ink are ejected according to the magenta input value in the CMYK input data, the yellow input value in the CMYK input data is minimum, and the black input value in the CMYK input data In the case where the recording rate of the magenta ink is 0 to a value greater than 0, the magenta input value is greater than the cyan input value in the CMYK input data than in the case where the cyan input value is minimum. The gist is that the one with the largest value is smaller.
The second printing apparatus of the present invention is a printing apparatus that prints an image with a plurality of colors of ink, and includes a nozzle for ejecting cyan ink, a nozzle for ejecting light cyan ink, and magenta ink. A nozzle for ejecting and a nozzle for ejecting yellow ink, and ejects the light cyan ink and the cyan ink according to the cyan input value in the CMYK input data, and the yellow in the CMYK input data. When the input value of the cyan ink is the minimum and the black input value of the CMYK input data is the minimum, the cyan input value where the cyan ink recording rate becomes a value greater than 0 is greater than 0 in the CMYK input data. The maximum magenta input value is smaller than the minimum magenta input value. It is the gist.
Furthermore, a third printing apparatus of the present invention is a printing apparatus that prints an image with a plurality of colors of ink, and includes a nozzle for ejecting cyan ink, a nozzle for ejecting light cyan ink, and magenta ink. A nozzle for ejecting and a nozzle for ejecting yellow ink, ejecting the light cyan ink and the cyan ink in accordance with the input value of R in the RGB input data, and B in the RGB input data When the input value of R is the maximum, the R input value at which the cyan ink recording rate becomes a value greater than 0 is greater than that when the G input value of RGB input data is the minimum. The gist is that the case where the input value of G is the maximum is smaller.
The present invention can also be grasped as a printing method.

In a printing apparatus according to another aspect of the present invention, a gradation signal of an image to be printed is input by an input unit, and based on the gradation signal, the dot generation unit has two or more types of light and dark inks. The dot recording density is obtained. When determining the recording density of such dots, the dot generating means has a characteristic in which dots with a high density ink appear with a gradation signal lower than the gradation signal with which the recording density of the dot with the low density ink becomes the maximum value. Based on this, processing is performed. As a result, the dots of the ink with the higher density begin to coexist before the recording density of the ink dots with the lower density reaches the maximum value, thereby realizing a smoother gradation expression.
Also, a printing apparatus which is another application column of the present invention inputs a gradation signal of an image to be printed by an input means, and based on this gradation signal, the dot generation means has two types of light and shade. The recording density of the above ink dots is obtained. In determining the recording density of such dots, in this printing apparatus, the dot generating means uses dots of low-density ink when the gradation signal is higher than the gradation signal at which the dot recording density of the low-density ink is maximum. The processing is performed based on the characteristic that the recording density of the recording medium sharply decreases. As a result, if the recording density of the low-density ink dots exceeds the maximum value and the high-density ink dots begin to mix, the recording density of the low-density ink dots decreases rapidly. Smoother gradation expression is realized.

  In such a printing apparatus using dark and light inks, the dot generating means may have a table that gives the recording density of each dot of the two or more light and dark inks from the inputted gradation signal. It is suitable.

  Also, when the dark and light ink is composed of two types of inks, if the dye density of the low density ink is set to about 1/4 of the dye density of the high density ink, the gradation change of what is actually printed feels most smoothly. It is done.

  As a head of such a printing apparatus, a head capable of ejecting two or more kinds of light and dark inks is provided for a plurality of inks having different hues, and the dot generating unit is configured to It is also desirable to provide each color dot generating means for performing processing for obtaining the recording density of each dot. In this case, it is possible to generate appropriate dark and light ink dots for a plurality of hue inks. The plurality of inks having different hues include cyan and magenta inks. In this case, each color dot generation means can be a means for performing the processing for cyan and magenta.

  Furthermore, each color dot generation means can be configured to determine the recording density of the dots in association with data of ink of other hues ejected to the corresponding pixel. In this case, the recording density of the light ink dots can be varied as compared with the case of the single color, and more appropriate dots can be formed in the case of color printing. In particular, if each color dot generation unit corrects the dot recording density of the low-density ink to be lower as the density of the other hue ink ejected to the corresponding pixel is higher, a plurality of colors of ink are ejected. Therefore, it is possible to reduce the discharge amount of the low-density ink and reduce the ink amount per unit area as a whole. As a result, printing can be performed with a margin with respect to the limit (ink duty) of the ink amount that can be ejected per unit area on the paper.

  Regarding the ink ejection method, various configurations can be adopted, and a configuration including a mechanism for ejecting ink particles by pressure applied to the ink by application of voltage to the electrostrictive element provided in the ink passage, A configuration including a mechanism for ejecting ink particles by a pressure applied to ink in the ink passage by bubbles generated by energization of a heating element provided in the ink passage may be employed. According to these configurations, it is easy to make the ink particles fine and control the ink amount appropriately, and it is also easy to prepare a large number of ejection nozzles on the head. In the case where a large number of nozzles are provided, a plurality of ink particle ejection nozzles can be arranged along the transport direction of the printed paper for each color and each density of ink. By preparing a plurality of nozzles, the printing speed can be improved.

A printing apparatus which is another application example of the present invention,
A plurality of inks having different hues can be ejected, and at least one of the plurality of inks is provided with a head capable of ejecting two or more kinds of light and dark inks. When input, the recording density of each dot of the plurality of inks having different hues is obtained based on the input gradation signal, and the light ink of the two or more types of light and dark inks is ejected to the corresponding pixel. The density of the dots is determined in relation to the density of the ink of other hues to be performed. Therefore, the recording rate of the low density ink is also related to the density of the ink of another hue.

  As an association between the recording rate of the low density ink and the density of the ink of another hue, the higher the density of the other hue ink ejected to the corresponding pixel, the lower the dot recording density of the low density ink. I can think of relationships. In this case, the recording rate of the low density ink can be reduced within a range that does not affect the apparent image quality, and the restriction on the ink duty can be relaxed.

  In addition, it is effective to have a look-up table that directly obtains the recording ratios of light and dark dots for a plurality of inks having different hues from the hue data of the original image in terms of speeding up the process of obtaining the recording ratio.

  The invention of the ink cartridge used in the printing apparatus described above is characterized in that two or more color inks having different densities are stored in a separate container from the black ink. Since this ink cartridge is housed in a separate container from the black ink, the replacement timing is affected by the exhaustion of the black ink used for printing centering on normal characters and the replacement timing. There is nothing.

  In such an ink cartridge, two or more types of inks having the same hue and different densities can be arranged at positions adjacent to each other. Specifically, two or more types of inks having different densities can be provided from one end. In this order, the cyan ink, the ink having a lower dye concentration than the cyan ink, the magenta ink, the ink having the lower dye concentration than the magenta ink, and the yellow ink can be arranged in this order.

Further, an image recording method as another application example of the present invention includes a head capable of ejecting two or more kinds of inks having different densities, respectively, and based on the gradation signal of the image to be recorded. A method for recording a multi-tone image by controlling the distribution of two or more types of ink dots,
Stores the characteristic that dots with high-density ink appear from the range of gradation signals lower than the gradation signal that maximizes the recording density of dots with low-density ink,
Input the gradation signal of the image to be printed,
According to the stored characteristics, from the input gradation signal, the presence or absence of two or more types of ink dots is determined,
The gist is to control the ejection of ink from the head in accordance with the determined presence / absence of dots, and to perform gradation expression based on the presence / absence of two or more types of ink dots.

In addition, an image recording method which is one of other application columns of the present invention,
A multi-tone image is provided by including a head capable of ejecting two or more types of light and dark inks having different densities, and controlling the distribution of dots of the two or more light and dark inks based on the tone signal of the image to be recorded. A method for recording
In the gradation signal higher than the gradation signal in which the dot recording density by the low density ink becomes the maximum value, the characteristic that the recording density of the dot by the low density ink is sharply reduced is stored,
Input the gradation signal of the image to be printed,
According to the stored characteristics, from the input gradation signal, the presence or absence of each dot of the two or more types of light and dark ink is determined,
The gist is to control the ejection of ink from the head in accordance with the determined presence / absence of dots, and to perform gradation expression based on the presence / absence of two or more types of ink dots.

In addition, an image recording method which is one of other application columns of the present invention,
An image recording method for recording an image by controlling the distribution density of dots formed by inks of different hues,
A plurality of inks having different hues can be ejected. For at least one of the plurality of inks, a head capable of ejecting two or more kinds of light and dark inks is used.
Input the gradation signal of the image to be printed,
Based on the input gradation signal, the recording density of each dot of the plurality of inks having different hues is obtained, and the light ink of the two or more types of light and light is discharged to the corresponding pixel. Determine the dot density in relation to the ink density of
The gist is to control the ejection of ink from the head to record the plurality of inks having different hues and the dots of the two or more kinds of light and shade on a recording material.

A recording medium which is one of the other applicable columns of the present invention is
A head capable of ejecting two or more kinds of light and dark inks having different densities is driven, and the distribution of dots of the two or more kinds of light and dark inks is controlled on the basis of a gradation signal of an image to be printed, so A recording medium on which at least a part of a program for forming an image is recorded so as to be readable by a computer,
A table storing characteristics of appearance of dots of high-density ink from a range of gradation signals lower than the gradation signal in which the recording density of dots of low-density ink is maximum;
A first program for inputting a gradation signal of an image to be printed;
The gist of the invention is that a second program for determining whether or not there are two or more kinds of light and dark ink dots is recorded from the input gradation signal in accordance with the stored characteristics.

In addition, the recording medium which is one of the other applicable columns of the present invention,
A head capable of ejecting two or more kinds of light and dark inks having different densities is driven, and the distribution of dots of the two or more kinds of light and dark inks is controlled on the basis of a gradation signal of an image to be printed, so A recording medium on which at least a part of a program for forming an image is recorded so as to be readable by a computer,
In a gradation signal higher than the gradation signal in which the dot recording density with the low density ink is the maximum value, a table storing characteristics in which the dot recording density with the low density ink sharply decreases,
A first program for inputting a gradation signal of an image to be printed;
The gist of the invention is that a second program for determining whether or not there are two or more kinds of light and dark ink dots is recorded from the input gradation signal in accordance with the stored characteristics.

Furthermore, the recording medium which is one of the other applied columns of the present invention is:
A plurality of inks having different hues can be ejected, and at least one of the plurality of inks is a dot formed by driving a head capable of ejecting two or more kinds of light and dark inks, and the inks having different hues A recording medium in which at least a part of a program for recording an image by controlling the distribution density is recorded so as to be readable by a computer,
A first program for inputting a gradation signal of an image to be printed;
Based on the input gradation signal, the recording density of each dot of the plurality of inks having different hues is obtained, and the light ink of the two or more types of light and light is discharged to the corresponding pixel. The gist is that the second program for determining the dot density is recorded in association with the ink density of the hue.

  As these recording media, various media such as ROM, RAM, flexible disk, CD-ROM, memory card, and other magneto-optical disks can be considered. Of course, a paper on which a bar code or the like is recorded, a card having a punch hole or the like according to a predetermined code system, and the like are also included. In addition, a program for determining the presence / absence of dots and the dot density is recorded on the recording medium described above, but there is a program for controlling ink ejection and the like in the head according to the determined presence / absence of dots and the determined dot density. This is because if the printer or computer is prepared in advance in the form of firmware, the program prepared on the recording medium is sufficient to obtain the presence / absence of dots and the dot density. When these firmwares are not prepared or when a program equivalent to these processes is prepared, a signal for controlling the ejection of ink from the head is output according to the determined dot presence / absence and dot density. The third program to be recorded may be recorded together with the recording medium. These first to third programs do not need to be recorded on a single recording medium, and may be recorded separately on several separated media. Needless to say, it may be recorded with predetermined encryption or compression.

Other aspects of the invention:
The present invention includes other aspects as follows. One is a configuration in which the input unit and the dot generation unit of the printing apparatus are placed not on the inside of the casing of the printing apparatus but on the side of the apparatus that outputs the image to be printed. The dot generation means can be realized by a discrete circuit, but can also be realized by software in an arithmetic logic circuit centered on the CPU. In the latter case, the side that outputs the image to be printed, for example, the computer side, performs processing related to dot generation, and the generated dots are ejected from the head into the casing of the printing apparatus. It is also possible to consider a form in which only the mechanism that is controlled and formed on the paper is stored. Of course, it is possible to divide the function of the dot generating means into several parts, realizing a part thereof in the casing of the printing apparatus and realizing the rest on the image output side.

  As another form, a form as a supply apparatus that supplies a program for realizing the above-described image recording method or a program recorded on the above-described recording medium via a communication line can be considered. In such a form, the above-described image recording method can be realized by placing a program on a server on a network, etc., downloading a necessary program to a computer via a communication line, and executing the program.

1 is a schematic configuration of a printing apparatus 10 according to a first embodiment of the present invention. 1 is a schematic configuration diagram of a printer 20 used in an embodiment. 3 is a block diagram illustrating a configuration of a control circuit 40 in the printer 20. FIG. 2 is a perspective view illustrating a configuration of a carriage 30. FIG. FIG. 6 is an explanatory diagram showing an arrangement of each color head 61 to 66 in the print head 28. 3 is a perspective view showing the shape of a color ink cartridge 70. FIG. FIG. 6 is an explanatory diagram illustrating a configuration for ejecting ink in each color head 61 to 66; It is explanatory drawing which shows a mode that the ink particle Ip is discharged by expansion | extension of the piezo element PE. FIG. 10 is a block diagram illustrating an example of processing from image information handled by a computer 90 to printing. It is explanatory drawing which shows the component of each color ink. It is a graph which illustrates the relationship between the recording rate and the brightness of each color ink. 10 is a flowchart illustrating an example of processing in the halftone module 99. It is a flowchart which shows the formation determination process routine of a dark dot. It is a graph which illustrates the relationship between the recording rate and gradation data by the light ink and dark ink in a present Example. It is explanatory drawing which shows an example of the threshold value matrix of the distributed dither for judging ON / OFF of a dark dot. It is explanatory drawing which shows an example of the weighting to each pixel in which an error is diffused in error diffusion. It is a flowchart which shows a light dot formation judgment processing routine. It is explanatory drawing which illustrates the mode of the dot formation by the light ink C2, and the dot formation by the dark ink C1 in a present Example. It is a graph which shows the other example of the relationship between the recording rate and gradation data by light ink and dark ink. It is a graph which shows the further another example of the relationship between the recording rate and gradation data by light ink and dark ink. It is a graph which calculates | requires the recording rate of the cyan ink in a 2nd Example. It is a graph which calculates | requires the recording rate of the magenta ink in 2nd Example. FIG. 10 is a block diagram illustrating a modified example of a printer driver 296. It is explanatory drawing which shows the look-up table which calculates | requires the recording rate of each color ink directly from RGB data. It is explanatory drawing which shows the other structural example of the discharge mechanism of an ink particle.

  Next, embodiments of the present invention will be described based on examples. As shown in FIG. 1, a printing apparatus 10 according to an embodiment of the present invention includes a computer 90 and a printer 20 connected thereto. A scanner 12 is further connected to the computer 90, and when a predetermined program is loaded and executed on the computer 90, it functions as the printing apparatus 10 having an image reading function as a whole. As shown in the figure, the computer 90 includes the following units connected to each other by a bus 80 with a CPU 81 that executes various arithmetic processes for controlling operations related to image processing according to a program. The ROM 82 stores programs and data necessary for executing various arithmetic processes by the CPU 81 in advance, and the RAM 83 temporarily reads and writes various programs and data necessary for the CPU 81 to execute various arithmetic processes. Memory. The input interface 84 controls input of signals from the scanner 12 and the keyboard 14, and the output interface 85 controls output of data to the printer 20. The CRTC 86 controls signal output to the CRT 21 capable of color display, and the disk controller (DDC) 87 controls data exchange with the hard disk 16, the flexible drive 15, or a CD-ROM drive (not shown). The hard disk 16 stores various programs loaded in the RAM 83 and executed, various programs provided in the form of device drivers, and the like. In addition, a serial input / output interface (SIO) 88 is connected to the bus 80. The SIO 88 is connected to the modem 18 and is connected to the public telephone line PNT via the modem 48. The computer 90 is connected to an external network via the SIO 88 and the modem 18, and a program necessary for image processing can be downloaded to the hard disk 76 by connecting to a specific server SV. It is also possible to load a necessary program from the flexible disk FD or CD-ROM and cause the computer 90 to execute it.

  As shown in FIG. 2, the printer 20 includes a mechanism for transporting the paper P by the paper feed motor 22, a mechanism for reciprocating the carriage 30 in the axial direction of the platen 26 by the carriage motor 24, and a print mounted on the carriage 30. It comprises a mechanism for driving the head 28 to control ink ejection and dot formation, and a control circuit 40 that controls the exchange of signals with the paper feed motor 22, carriage motor 24, print head 28 and operation panel 32. ing.

  The mechanism for transporting the paper P includes a gear train that transmits the rotation of the paper feed motor 22 not only to the platen 26 but also to a paper transport roller (not shown). In addition, the mechanism for reciprocating the carriage 30 includes an endless drive belt 36 that is stretched between the carriage motor 24 and a slide shaft 34 that is laid in parallel with the platen 26 shaft and slidably holds the carriage 30. And a position detection sensor 39 for detecting the origin position of the carriage 30.

  The configuration of the printer 20 centering on the control circuit 40 will be described with reference to FIG. As shown in the figure, the control circuit 40 is configured as an arithmetic and logic circuit centered on a known CPU 41, a P-ROM 43 storing a program, a RAM 44, a character generator (CG) 45 storing a dot matrix of characters, and the like. In addition, an I / F dedicated circuit 50 dedicated to interface with an external motor or the like, a head drive circuit 52 connected to the I / F dedicated circuit 50 to drive the head 28, and also the paper feed motor 22 And a motor drive circuit 54 for driving the carriage motor 24. The I / F dedicated circuit 50 has a built-in parallel interface circuit, and is connected to the computer via the connector 56 and can receive a printing signal output from the computer. The output of the image signal from the computer will be described later.

  Next, a specific configuration of the carriage 30 and the principle of ink ejection by the print head 28 mounted on the carriage 30 will be described. As shown in FIG. 4, the carriage 30 has a substantially L-shape, and can mount a black ink cartridge and a color ink cartridge 70 (not shown), and a partition plate 31 that partitions both cartridges so that they can be mounted. Is provided. As shown in FIG. 5, a total of six ink ejection heads 61 to 66 are formed on the print head 28 below the carriage 30. At the bottom of the carriage 30, each color head is connected to an ink tank. Introducing pipes 71 to 76 for guiding the ink. When the black ink cartridge and the color ink cartridge 70 are mounted on the carriage 30 from above, the introduction pipes 71 to 76 are inserted into the connection holes provided in the cartridges.

  A mechanism for ejecting ink will be briefly described. When the ink cartridge 70 shown in FIG. 6 is mounted on the carriage 30, the ink in the ink cartridge is sucked out through the introduction pipes 71 to 76 using the capillary phenomenon, and as shown in FIG. They are guided to the respective color heads 61 to 66 of the print head 28 provided at the lower part of the carriage 30. As shown in FIGS. 5 and 7, each color head 61 to 66 is provided with nozzles n for each color in a line. In this embodiment, the number of nozzles for each color is 32. A piezo element PE is arranged for each nozzle n. As is well known, the piezo element PE is an element that transforms electro-mechanical energy at a very high speed because the crystal structure is distorted by application of a voltage. FIGS. 8A and 8B show the structures of the piezo element PE and the nozzle n in detail. As shown in the drawing, the piezo element PE is installed at a position in contact with the ink passage 68 that guides ink to the nozzle n. In this embodiment, when a voltage having a predetermined time width is applied between the electrodes provided at both ends of the piezo element PE, the piezo element PE rapidly expands as shown in FIG. One side wall of 68 is deformed. As a result, the volume of the ink passage 68 contracts in accordance with the expansion of the piezo element PE, and the ink corresponding to the contraction becomes particles Ip and is ejected from the tip of the nozzle n at high speed. Printing is performed by the ink particles Ip soaking into the paper P mounted on the platen 26.

  The arrangement of the color heads 61 to 66 in the print head 28 is divided into three groups, with two heads as one set, as shown in FIG. 5, in view of the arrangement of the piezo elements PE described above. . A black ink head 61 is disposed at an end on the side close to the black ink cartridge, and a cyan ink head 62 is adjacent to the black ink head 61. Adjacent to this set are a head 63 for ink (hereinafter referred to as light cyan ink) having a lower density than the cyan ink supplied to the cyan ink head 62 and a magenta ink head 64. In the next set, a head 65 for ink having a lower density than normal magenta ink (hereinafter referred to as light magenta ink) and a yellow head 66 are arranged. The composition and concentration of each ink will be described later.

  The printer 20 of the present embodiment having the hardware configuration described above rotates the platen 26 and other rollers by the paper feed motor 22 and conveys the paper P, while the carriage 30 is reciprocated by the carriage motor 24 and simultaneously prints. The piezo elements PE of the respective color heads 61 to 66 of the head 28 are driven to discharge the respective color inks, thereby forming a multicolor image on the paper P. As shown in FIG. 9, the printer 20 forms a multicolor image based on a signal received from an image forming apparatus such as a computer 90 via the connector 56. In this example, the application program operating inside the computer 90 displays an image on the CRT display 93 via the video driver 91 while processing the image. When the application program 95 issues a print command, the printer driver 96 of the computer 90 receives image information from the application program and converts it into a signal that the printer 20 can print. In the example shown in FIG. 9, the printer driver 96 includes a rasterizer 97 that converts image information handled by the application program 95 into color information in dot units, and image information (floor level) converted into color information in dot units. Color correction module 98 that performs color correction according to the color development characteristics of the image output apparatus (printer 20 in this case) on the tone data), and an area depending on the presence or absence of ink in dot units from the image information after color correction. A halftone module 99 for generating so-called halftone image information expressing the density of the image is provided. Since the operation of each of these modules is well known, description thereof will be omitted in principle, and the contents of the halftone module 99 will be described as necessary.

  As described above, the printer 20 of this embodiment includes the heads 63 and 65 for light cyan ink and light magenta ink in addition to the so-called CMYK four color inks. These inks are obtained by reducing the dye concentrations of ordinary cyan ink and magenta ink as shown in FIG. As shown, the normal density cyan ink (indicated by C1 in FIG. 10) is 3.6 weight percent direct blue 199 dye, 30 weight percent diethylene glycol, 1 weight percent Surfinol 465, 65.4 water. In contrast to the weight percent, the light cyan ink (indicated by C2 in FIG. 10) and the direct blue 199 dye are set to 0.9 weight percent, which is 1/4 of the cyan ink C1, to adjust the viscosity. Therefore, diethylene glycol is changed to 35 weight percent and water is changed to 63.1 weight percent. Further, the normal concentration of magenta ink (indicated by M1 in FIG. 10) is 2.8% by weight of acid red 289, 20% by weight of diethylene glycol, 1% by weight of Surfinol 465, and 76.2% by weight of water. In contrast, light magenta ink (indicated by M2 in FIG. 10) is acid red as a dye, 0.7 weight percent that is 1/4 of magenta ink M1, 25 weight percent diethylene glycol, water. This is changed to 73.3 weight percent.

  As shown in FIG. 10, the yellow ink Y and the black ink K use direct yellow 86 and hood black 2 as dyes and are 1.8 weight percent and 4.8 weight percent, respectively. . In any ink, the viscosity is adjusted to about 3 [mPa · s]. Since the viscosity is adjusted to be the same, the control of the piezo element PE for each color head can be made the same.

  FIG. 11 shows the measured brightness of each color ink. The horizontal axis of FIG. 11 is the recording rate with respect to the recording resolution of the printer, and indicates the ratio of dots recorded on the white paper P by the ink particles Ip ejected from the nozzles n. That is, the recording rate 100 indicates a state where the entire surface of the paper P is covered with the ink particles Ip. In this embodiment, the density of the dye of the light cyan ink C2 is about 1/4 by weight percent with respect to the cyan ink C1, and the lightness of both inks at this time is when the recording rate of the light cyan ink C2 is 100%. Is equal to the lightness when the recording rate of the cyan ink C1 is about 35%. This relationship is the same for the magenta ink M1 and the light magenta ink M2. The ratio of the recording rate at which inks with different densities have the same brightness is determined from the point of view of the beauty of color mixing when both inks are mixed, but in practice it is in the range of 20 to 50 percent. It is desirable to adjust. When this relationship is expressed as a percentage by weight of the dye in both inks, the low density ink (light cyan ink C2 and light magenta) with respect to the weight percentage of dye in the high density ink (cyan ink C1 and magenta ink M1). The relationship of the weight percentage of the dye in the ink M2) is almost equivalent to the latter being adjusted to about 1/5 to 1/3 of the former.

  Next, according to the processing in the halftone module 99 of the printer driver 96, the manner of printing using dark and light inks in the printer 20 of this embodiment will be described. FIG. 12 is a flowchart showing an outline of the processing of the halftone module 99.

  As shown in the figure, when the printing process is started, each pixel is scanned in turn with the upper left corner of one image as the origin. First, one pixel is sequentially selected from the color correction module 98 in the order along the scanning direction of the carriage 30. Color-corrected gradation data DS (8 bits for each of CMYK) is input (step S100).

  In the following description, it is assumed that printing is performed only with cyan ink. However, in practice, multicolor printing is performed, and for magenta, magenta ink M1 having a high density and light magenta ink having a low density are used. A dark dot and a light dot are formed by M2. For yellow, dots are formed by the yellow ink Y, and for black, dots are formed by the black ink K. Also, when dots with different color inks are formed in a predetermined area, control necessary to improve color reproducibility by color mixing, for example, printing different color dots at the same position Control that is not to be performed is performed.

  Next, based on the input gradation data DS, processing for determining on / off of dark dots is performed (step S120). Details of the processing for determining whether the dark dots are on or off will be described in accordance with the dark dot formation determination processing routine of FIG. In this processing routine, first, processing for generating dark level data Dth is performed based on the gradation data DS with reference to the table shown in FIG. 14 (step S122). FIG. 14 shows a table for setting the recording ratio of light ink and dark ink with respect to the gradation data of the original image. Since the gradation data takes values from 0 to 255 for each color (each color is 8 bits), the gradation data size is expressed as 16/256 or the like. The table of FIG. 14 shows the average ratio of dark ink and light ink in the obtained printed matter, and the average recording of dark ink and light ink to be realized when a certain gradation data DS is given. Give rate. Therefore, it is not uniquely determined whether dots are turned on / off by dark ink or light ink of each pixel.

  Based on the input gradation data DS, the dark level data Dth corresponding to a predetermined dark ink recording rate is obtained by referring to the table of FIG. 14 (right-hand vertical axis in FIG. 14). For example, when the input cyan gradation data is printed in a solid area of 50/256, the recording rate of the cyan ink C1, which is dark ink, is 0%, and the dark level data also has a value of 0. When printing a solid area with gradation data of 95/256, the recording rate of cyan ink C1, which is dark ink, is 7%, and dark level data Dth has a value of 18. Further, when printing a solid area with gradation data of 191/256, the recording rate of cyan ink C1 is 75% and the dark level data is 191. Note that the recording rates of the corresponding light cyan ink C2 in these cases are 36%, 58%, and 0%, and the light level data Dtn is 92/255, 148/255, 0/255, respectively.

Furthermore, the relationship between the recording rate of the light cyan ink C2 and the recording rate of the cyan ink C1 shown in FIG. 14 has the following characteristics.
(1) In an area where the input gradation data is low (in the embodiment, 0/256 to 63/256), only light cyan ink C2 is recorded. The recording rate increases monotonously according to the size of the gradation data.
(2) Before the recording rate of the light cyan ink C2, which becomes a large value in accordance with the increase of the input gradation data, becomes the maximum value (58% in the embodiment), according to the increase of the gradation data, Dot formation is started with the cyan ink C1, which is a high-density ink, and the recording rate gradually increases. In the embodiment, when the input gradation data exceeds 63/256, a dot of cyan ink C1 is formed. Note that the value of the gradation data that maximizes the recording rate with the light cyan ink C2 is 95/256 in the embodiment.

(3) When the gradation data becomes larger than the value at which the recording rate of the light cyan ink C2 becomes the maximum value, the recording rate of the light cyan ink C2 rapidly decreases. On the other hand, the recording rate of cyan ink C1 increases almost in proportion to the increase in gradation data. In the embodiment, when the gradation data exceeds 127/256, the recording rate of the light cyan ink C2 decreases rapidly, and when the gradation data exceeds 191/256, the recording rate becomes almost zero.
(4) In the region where the gradation data is larger than the value at which the recording rate of the light cyan ink C2 is substantially 0, the recording rate of the cyan ink C1 increases sequentially to the maximum value of 100% as the gradation data increases. Compared with the area before that, the rate of increase of the recording rate with respect to the increase of the gradation data is slightly lower.

  In the present embodiment, the following processing is performed for obtaining dark level data Dth using this relationship shown in FIG. 14 and determining whether dark ink is on or off. First, it is determined whether or not the dark level data Dth thus obtained is larger than the threshold value Dref1 (FIG. 13, step S124). The threshold value Dref1 is a determination value as to whether or not to form a dot with dark ink on the pixel of interest. In this example, a threshold matrix of a distributed dither is adopted for setting the threshold, and a systematic dither method is applied using a global matrix (blue noise matrix) of about 64 × 64 in particular. Accordingly, the threshold value Dref1 for determining the on / off state of the dark dot has a different value for each pixel of interest. FIG. 15 shows the concept of threshold values in the systematic dither method. In FIG. 15, the size of the matrix is set to 4 × 4 for convenience of illustration, but actually, a 64 × 64 size matrix is used, and any 16 × 16 area inside the matrix is used as a threshold value (0). The threshold is determined so that there is no bias in the appearance of .about.255). When such a global matrix is used, the occurrence of pseudo contours is suppressed. The distributed dither is a type in which the dot spatial frequency determined by the threshold matrix is high, and the dots are generated in a disjoint manner in the region. Specifically, a Beyer-type threshold matrix is known. When a distributed dither is used, dark dots are generated in a discrete manner, so that the distribution of dark and light dots is not biased and the image quality is improved. It should be noted that other methods such as a density pattern method or a pixel distribution method may be employed to determine whether dark dots are turned on or off.

  If the dark dot data Dth is larger than the threshold value Dref1, it is determined that the dark dot of the pixel is to be turned on, and a process for calculating the result value RV is performed (FIG. 13, step S126). The result value RV is a value (dark dot evaluation value) corresponding to the density of the pixel. When it is determined that the dark dot is on, that is, a dot with high density ink is formed on the pixel, the density of the pixel is determined. A corresponding value (for example, value 255) is set. The result value RV may be a fixed value or may be set as a function of the dark level data Dth.

  On the other hand, if the dark level data Dth is equal to or less than the threshold value Dref1, it is determined that the dark dots are off, that is, not formed, and a process of substituting the value 0 into the result value RV is performed (step S128). Since the white background of the paper remains in a portion where dots with high density ink are not formed, the result value RV is set to 0.

After dark dot on / off is determined and the result value RV is calculated (step S120 in FIG. 12), light dot data Dx for determining light dot on / off is obtained. Processing is performed (step S130), and a diffusion error ΔDu from the processed pixel is added to this to perform processing for obtaining correction data DC (step S135). The light dot data Dx is obtained by the following equation.
Dx = Dth · Z / 255 + Dtn · z / 255
Here, Dtn is light dot data obtained from the gradation data DS based on the graph of FIG. Z is an evaluation value when a dark dot is formed, and here is a value 255 as described above. Therefore, the above equation is
Dx = Dth + Dtn · z / 255
It becomes. Z is an evaluation value when a light dot is formed. In the case of a light dot, even when a dot is formed, the evaluation is small compared to a dark dot. In this embodiment, z = 160.

  The reason why the correction data DC is obtained by adding the diffusion error ΔDu to this is that error diffusion processing is performed for the light dots. When printing by error diffusion, shading errors generated for processed pixels are distributed in advance with a predetermined weight assigned to pixels around the pixels. Therefore, the corresponding error is read and reflected in the pixel to be printed from now on. FIG. 16 illustrates how the error is distributed to which pixels around the processed pixels PP for which on / off of light dots has been determined, and to which pixels are processed. Density error is a predetermined weight (1/4, 1) for several pixels in the scanning direction of the carriage 30 and several adjacent pixels on the rear side in the conveyance direction of the paper P with respect to the pixel PP determined to be on / off. / 8, 1/16).

  After obtaining the correction data DC, it is determined whether or not dark dots are turned on (dot formation with cyan ink C1) (step S138). If dark dots are not formed, dots with low density, Processing for determining on / off of dots (hereinafter referred to as light dots) by the light cyan ink C2 is performed (step S140). The process for determining whether the light dot is on or off will be described with reference to the light dot formation determination process routine shown in FIG. In the process of determining on / off of the light dot, in this example, the dot formation by the light cyan ink C2 is performed by applying the error diffusion method, and the gradation data DC corrected by the concept of error diffusion is the threshold Dref2 for the light dot. It is determined whether or not it is larger (step S144). This threshold value Dref2 is a determination value as to whether or not to form dots of light ink with low density on the pixel of interest, and is set to a fixed value 127 in this embodiment. It is also possible to set the threshold value Dref2 as a value that can be varied according to the corrected data DC. For example, if the threshold value Dref2 is a function of the correction data DC to be determined and the threshold value Dref2 is set to the minimum value and the maximum value near the minimum value and the maximum value of the correction data DC, respectively, It is possible to suppress the dot formation delay near the lower limit or the upper limit and the dot formation disorder (so-called tailing) that occurs in a certain range in the scanning direction when the gradation of the region suddenly changes.

  If the correction data DC is larger than the threshold value Dref2, it is determined that the light dot is turned on, and the result value RV (light dot evaluation value) is calculated (step S146). Here, the result value RV is a value that is corrected by the correction data DC using the value 122 as a reference value, but may be a fixed value. On the other hand, if it is determined that the correction data DC is equal to or less than the threshold value Dref2, it is determined to turn off the light dot, and a process of adding the value 0 to the result value RV is performed (step S148).

  After light dots are turned on / off and the result value RV is calculated in this way (FIG. 12, step S140), error calculation is then performed (step S150). The error calculation is obtained by subtracting the result value RV from the correction data DC. When neither dark nor light dots are formed, the result value RV is set to 0, so that the correction value DC is included in the error ERR. That is, since the density to be realized in the pixel is not obtained at all, the density is calculated as an error. On the other hand, when dark dots or light dots are formed, since the result value RV corresponding to each dot is substituted, the difference from the data DC from which the determination is made becomes an error ERR.

  Next, error diffusion processing is performed (step S160). A predetermined weight (see FIG. 16) is given to the error obtained in step S150, and this error is diffused to the peripheral pixels of the pixel being processed. After the above processing, the process moves to the next pixel, and the processing from step S100 onward is repeated.

  In this way, recording with light dots and dark dots is performed. FIG. 18 schematically shows this state for the cyan ink C1 and the light cyan ink C2. In the region where the input gradation data is low (in the embodiment, the region where the gradation data is 0/256 to 63/256), as shown in FIGS. 18A and 18B, only the dots of the light cyan ink C2 are used. As the gray level data becomes higher and the gradation data becomes higher, the proportion of light dots existing in the predetermined area increases.

  In a region where the gradation data exceeds a predetermined value (in the embodiment, a region of 64/256 or more), as shown in FIG. 18C, the ratio of light dots increases, but recording of dark dots is started and gradually. To increase. Further, in an area where the gradation data is high (in the embodiment, an area of 95/256 or more), as shown in FIGS. 18D and 18E, the dark dots increase and the ratio of the light dots decreases. Go.

  When the gradation data becomes a higher region (in the embodiment, a region of 191/256 or more), light dots are not formed, and only dark dots are formed as shown in FIGS. 18 (f) and 18 (g). Is done. When the gradation data is maximized, as shown in FIG. 18 (h), the recording rate of dark dots is 100%, and the entire surface of the paper P is printed with a high-density ink (cyan ink C1). .

  As described above, the printer 20 using the dark and light ink according to the present embodiment records an image using two types of inks whose dye concentrations are different by about 4 times. The print quality is improved with a focus on resolution. Moreover, as shown in FIG. 14, the ink with high density (cyan ink C1 in FIG. 14) from the area below the gradation data where the recording rate of the light dots with the low density ink (light cyan ink C2 in FIG. 14) becomes the maximum. Since the formation of dark dots is started, the color mixture at the joint from the recording with the light dots to the recording with the dark dots is extremely smooth, and the print quality is extremely high.

  Further, since the dot formation with the dark ink is started from the area below the gradation data where the recording rate of the light ink is maximum, the maximum recording rate of the light ink can be about 60%. . As a result, the state of solid coating with light ink does not occur in an area where the gradation is low, and a pseudo contour does not occur in the vicinity of the gradation. Further, the degree of freedom of dot distribution by dark ink is high, and it is possible to obtain a clean distribution that does not give a sense of incongruity. As a result, the expression in the vicinity of the gradation at which high density ink and low density ink begin to mix is extremely natural.

  Further, in a region larger than the gradation at which the light ink recording rate is maximized, the light ink recording rate is rapidly decreased. Therefore, as the gradation increases, the light ink dots are replaced with dark ink dots, and the number of ink dots necessary to express the same gradation, that is, the discharge amount, is reduced, and as a whole. The amount of ink used can be reduced. As a result of rapidly decreasing the recording rate of the light ink, the recording rate of the light ink is almost zero long before the recording rate of the dark ink reaches 100 percent (input data 255). Therefore, when printing an area where the gradation of the image is dark, not only is the light ink used unnecessarily, but the amount of ink ejected as a whole can be reduced. It is also preferable from the aspect of restriction.

  Note that the relationship between the size of the gradation data and the recording rate using light ink and dark ink is not limited to that shown in FIG. 14. For example, as shown by straight lines Jc 1 and Jc 2 in FIG. The gradation data whose formation is started has a characteristic that is considerably lower than that of the above-described embodiment, and the gradation data in which the recording rate by the light ink is reduced to almost zero as shown by the broken lines Bc1 and Bc2 in FIG. It is also possible to adopt a characteristic in which the value is considerably larger than that in the above embodiment. Also, as shown in FIG. 20, it is possible to have a characteristic that reduces the recording rate of the light ink at a very large ratio in the area of the gradation data or more where the recording rate of the light ink becomes the maximum value.

  In this embodiment, since the black ink cartridge and the color ink cartridge 70 are separated, the color ink cartridge is used in conjunction with the exhaustion of the black ink often used for printing normal characters and the replacement time. There is no need to change up to 70. The arrangement of the color inks in the color ink cartridge 70 is such that inks of the same color (cyan or magenta) and different densities are adjacent to each other, and the physical distance from the high density ink to the low ink is the same for each ink. ing. Therefore, it is possible to accurately control the dot position when both dark and light inks are printed. In this embodiment, since a large number of nozzles are prepared along the conveyance direction of the paper P, high-speed printing is possible as a whole.

  Although one embodiment of the present invention has been described above, the present invention is not limited to such an embodiment, and can of course be implemented in various modes without departing from the gist of the present invention. . For example, it is possible to use three or more types of inks having different densities. In this case, the dye density ratio of the ink may be a geometric series (1: n: 2 × n ···) or a power relationship (1: n2: n4 ···). Here, n = 2, 3,...

  In this embodiment, two types of ink having different densities are prepared only for cyan and magenta, but it is also possible to use a combination of inks having different densities for yellow and black. The ink is not limited to the combination of CMYK, and may be applied to other combinations, and two or more kinds of inks having different densities for special colors such as gold and silver may be used.

  In this embodiment, the program for controlling the dark and light dots is prepared not on the printer 20 side but on the printer driver 96 side of the computer 90. However, it can also be prepared in the printer 20. For example, when image information to be printed is sent from the computer 90 in a language such as Postscript, the printer 20 has a halftone module 99 or the like. In this embodiment, a software program that realizes these functions is stored in a hard disk or the like in the computer 90, and is incorporated into the operating system in the form of a printer driver when the computer 90 starts up. Or a portable storage medium (portable storage medium) such as a CD-ROM, and transferred from the portable storage medium to the main memory of the computer system or an external storage device. It is also possible to transfer the information from the computer 90 to the inside of the printer 20 for use. It is also possible to provide a device that provides the software program via a communication line, and transfer the processing contents of the halftone module to the computer or printer 20 via the communication line. it can.

  Next, a second embodiment of the present invention will be described. The printer 200 of the second embodiment has the same hardware configuration as the printer 20 of the first embodiment, and only the processing in the halftone module 99 in the computer 90 is different. That is, in the processing in the halftone module, when obtaining the recording ratio of dark and light ink from the gradation data of the pixels of the original image, the first embodiment refers to the relationship shown in FIG. In the embodiment, the graph shown in FIG. 21 is referred to. That is, in this embodiment, as shown in FIGS. 21A and 21B, the recording rate of the light ink dots and the recording rate of the dark ink dots of the color currently processed by the halftone module 99 are shown. Not only the gradation data of ink, for example, cyan ink, but also the gradation data of other colors of the pixel of interest, here the gradation data of magenta ink. Specifically, with regard to cyan ink, when there is a large amount of magenta ink to be ejected corresponding to the pixel of interest, the recording rate of light cyan ink C2 of cyan ink is reduced overall, Accordingly, the recording rate of cyan ink C1 is increased. Similarly, as shown in FIGS. 22A and 22B, for magenta ink, if the amount of cyan ink to be ejected corresponding to the pixel of interest is large, The recording rate of the light magenta ink M2 is decreased as a whole, and the recording rate of the magenta ink M1 is increased accordingly.

  In the embodiment described above, as in the first embodiment, two types of inks having different dye concentrations are used to record an image, and in particular, the recording rate of light dots using a low-density ink (light cyan ink C2 in FIG. 14). Since the formation of dark dots with a high-density ink (cyan ink C1 in FIG. 14) is started from the area below the gradation data where the maximum is, the color mixture at the joint from the recording with the light dots to the recording with the dark dots is It is extremely smooth and has the characteristics of extremely high print quality. In this embodiment, the higher the ink density of other colors for the same pixel, the lower the recording rate of the ink (C2 or M2) with the lower density, and the corresponding amount is transferred to the ink with the higher density (C1 or M1). However, since there is bleeding of the ink of other colors, the granulation is not conspicuous as compared with the case of the single color.

  Further, in this embodiment, as in the first embodiment, the formation of dots by dark ink is started from the area below the gradation data where the recording rate of the light ink is maximum. In the case of light ink, the generation of dark ink dots is accelerated and the generation of dark ink dots is accelerated. Also in this case, the naturalness of the expression in the vicinity of the gradation at which the high density ink and the low density ink start to be mixed is not impaired.

  As a result, the recording rate of cyan ink or magenta ink recorded at a position corresponding to the pixel of interest is high when the recording rate of magenta ink or cyan ink recorded corresponding to the same pixel is high. Since the low-density ink (C2 or M2) is replaced with the high-density ink (C1 or M1), the total amount of ink ejected per unit area can be reduced without degrading the image quality. Accordingly, each color ink can be ejected with a sufficient margin with respect to the limit on the amount of ink that can be ejected per unit area determined for each sheet (so-called ink duty). As a result, the paper does not swell with ink and does not become an unnatural color due to ink duty limitations.

  In the second embodiment, for the pixel of interest, cyan density (gradation data), magenta density (gradation data), and yellow density (gradation) necessary for expressing the hue of the pixel of interest. In the print driver, the dot recording rate of the dark and light inks is determined based on these correlations. However, within the print driver, each color is directly determined from the RGB data of the pixel of interest. It is also possible to obtain the dot recording rate with dark and light inks. That is, as shown in FIG. 23, a rasterizer 297, a color correction / halftone module 299, and a lookup table 300 are provided in the print driver 296, and after the RGB data for each pixel is obtained by the rasterizer 297, the RGB By referring to the look-up table based on the data, it is also possible to obtain the recording ratio of the dark and light inks for cyan and magenta and the recording ratio for the yellow ink directly. FIGS. 24A and 24B show an example of a look-up table for obtaining the cyan ink recording rate directly from the RGB data of the pixel of interest.

  This configuration example has an advantage that the configuration can be simplified because the recording rate of each color ink can be obtained directly from the RGB data. In the second embodiment and its modification, the higher the density of magenta (or cyan), the lower the recording rate of light ink dots for cyan (or magenta), and the dark ink recording rate. However, it is also possible to change the recording ratio of the dark and light inks depending on the yellow density. In addition, when the recording rates of cyan, magenta, and yellow inks are not zero for the pixel of interest, printing is performed by replacing the three colors with black ink, and depending on the density of the black ink, light cyan ink The recording rate of C2 and light magenta ink M2 may be reduced, and the recording rate of cyan ink C1 and magenta ink M1 may be increased.

  In some of the above-described embodiments, the recording rate of the light cyan ink C2 and the light magenta ink M2 is lowered as a whole due to the magenta density and cyan density at the position corresponding to the pixel of interest. It is not limited to relationships. That is, the dot recording rate of the light ink and the dot recording rate of the dark ink can be freely determined according to the density of the other ink at the position corresponding to the pixel of interest. For example, when a plurality of inks are ejected so as not to meet the ink duty limit, when the recording rate of light ink is reduced or when pixels with cyan, magenta, and yellow are replaced with black, dark ink is used. It is possible to take measures such as temporarily reducing the amount of light ink and increasing the graininess of the joints.

  Further, in the above-described embodiment, both the dark and light inks are ejected by using the piezo element PE and applying a voltage having a predetermined time width to the piezo element PE. However, other ink ejection methods are employed. It is also easy. Ink discharge methods that have been put into practical use are roughly divided into a method that separates and discharges ink particles from a continuous ink jet, and an on-demand method that is also used in the above-described embodiments. The The former includes a charge modulation method in which droplets are split from an ink jet by charge modulation, and a microdot method in which minute satellite particles generated when large diameter particles are split from an ink jet are used for printing. Yes. These methods are also applicable to the printing apparatus of the present invention using a plurality of types of ink concentrations.

  The on-demand method generates ink particles when ink particles are required in units of dots. In addition to the method using the piezo element employed in the above-described embodiment, the on-demand method is also illustrated in FIG. As shown in (E), a method is known in which a heating element HT is provided in the vicinity of the ink nozzle NZ, the bubble BU is generated by heating the ink, and the ink particles IQ are ejected by the pressure. These on-demand ink ejection methods can also be applied to the printing apparatus of the present invention that uses a plurality of types of ink concentrations.

DESCRIPTION OF SYMBOLS 20 ... Printer 22 ... Paper feed motor 24 ... Carriage motor 25 ... Diethylene glycol 26 ... Platen 28 ... Print head 30 ... Carriage 31 ... Partition plate 32 ... Operation panel 34 ... Sliding shaft 36 ... Drive belt 38 ... Pulley 39 ... Position detection sensor 40 ... Control circuit 41 ... CPU
43 ... ROM
44 ... RAM
DESCRIPTION OF SYMBOLS 50 ... I / F exclusive circuit 52 ... Head drive circuit 54 ... Motor drive circuit 56 ... Connector 61-66 ... Ink ejection head 68 ... Ink passage 70 ... Color ink cartridge 71 ... Introducing pipe 90 ... Computer 91 ... Video driver 93 ... CRT display 95 ... Application program 96 ... Printer driver 97 ... Rasterizer 98 ... Color correction module 99 ... Halftone module P ... Paper PE ... Piezo element n ... Nozzle

Claims (16)

A printing apparatus that prints an image with multiple colors of ink ,
A nozzle for ejecting magenta ink;
A nozzle for discharging light magenta ink;
Nozzles for discharging cyan ink;
Nozzles for discharging yellow ink
With
The light magenta ink and the magenta ink are ejected in accordance with the magenta input value in the CMYK input data,
In the case where the yellow input value in the CMYK input data is minimum and the black input value in the CMYK input data is minimum, the magenta input value at which the magenta ink recording rate becomes a value greater than 0 is 0. The printing apparatus is smaller when the cyan input value is the maximum than when the cyan input value is the minimum in the CMYK input data . It has a nozzle for discharging light cyan ink,
The printing apparatus according to claim 1, wherein the cyan ink and the light cyan ink are ejected in accordance with the cyan input value. A printing apparatus that prints an image with multiple colors of ink,
Nozzles for discharging cyan ink;
A nozzle for ejecting light cyan ink;
A nozzle for ejecting magenta ink;
A nozzle for discharging yellow ink, and
According to the input value of cyan in the input data of CMYK, the light cyan ink and the cyan ink are ejected,
In the case where the yellow input value in the CMYK input data is minimum and the black input value in the CMYK input data is minimum, the cyan input value where the cyan ink recording rate becomes a value greater than 0 is 0. A printing apparatus in which the input value of magenta is smaller than the input value of magenta in the input data of CMYK is smaller. It has a nozzle for discharging light magenta ink,
The printing apparatus according to claim 3, wherein the magenta ink and the light magenta ink are ejected in accordance with an input value of the magenta. A printing apparatus that prints an image with multiple colors of ink,
Nozzles for discharging cyan ink;
A nozzle for ejecting light cyan ink;
A nozzle for ejecting magenta ink;
A nozzle for discharging yellow ink, and
According to the input value of R in the RGB input data, the light cyan ink and the cyan ink are ejected,
When the B input value in the RGB input data is the maximum, the R input value where the cyan ink recording rate is 0 to a value greater than 0 is the smallest in the G input value in the RGB input data. The printing apparatus is smaller when G is maximum than in the case of.   The printing apparatus according to claim 5, further comprising a nozzle for discharging light magenta ink.   The printing apparatus according to claim 5, wherein a recording rate of the light cyan ink is obtained from RGB input data using a lookup table.   The printing apparatus according to claim 1, further comprising a nozzle for discharging black ink. A printing method for printing an image by a printing apparatus,
The printing apparatus includes a nozzle for ejecting magenta ink, a nozzle for ejecting light magenta ink, a nozzle for ejecting cyan ink, and a nozzle for ejecting yellow ink.
The light magenta ink and the magenta ink are ejected in accordance with the magenta input value in the CMYK input data,
In the case where the yellow input value in the CMYK input data is minimum and the black input value in the CMYK input data is minimum, the magenta input value at which the magenta ink recording rate becomes a value greater than 0 is 0. The printing method is smaller when the cyan input value is the maximum than when the cyan input value is the minimum in the CMYK input data. The printing apparatus includes a nozzle for discharging light cyan ink,
The printing method according to claim 9, wherein the cyan ink and the light cyan ink are ejected in accordance with the cyan input value. A printing method for printing an image by a printing apparatus,
The printing apparatus includes a nozzle for discharging cyan ink, a nozzle for discharging light cyan ink, a nozzle for discharging magenta ink, and a nozzle for discharging yellow ink.
According to the input value of cyan in the input data of CMYK, the light cyan ink and the cyan ink are ejected,
In the case where the yellow input value in the CMYK input data is minimum and the black input value in the CMYK input data is minimum, the cyan input value where the cyan ink recording rate becomes a value greater than 0 is 0. The printing method is smaller when the input value of magenta is the maximum than when the input value of magenta in the input data of CMYK is the minimum. The printing apparatus includes a nozzle for discharging light magenta ink,
The printing method according to claim 11, wherein the magenta ink and the light magenta ink are ejected according to an input value of the magenta. A printing method for printing an image by a printing apparatus,
The printing apparatus includes a nozzle for discharging cyan ink, a nozzle for discharging light cyan ink, a nozzle for discharging magenta ink, and a nozzle for discharging yellow ink.
According to the input value of R in the RGB input data, the light cyan ink and the cyan ink are ejected,
When the B input value in the RGB input data is the maximum, the R input value where the cyan ink recording rate is 0 to a value greater than 0 is the smallest in the G input value in the RGB input data. The printing method is smaller when the input value of G is the maximum than in the case of.   The printing method according to claim 13, wherein the printing apparatus includes a nozzle for ejecting light magenta ink.   The printing method according to claim 13 or 14, wherein a recording rate of the light cyan ink is obtained from RGB input data using a lookup table.   The printing method according to claim 9, wherein the printing apparatus includes a nozzle for discharging black ink.

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